胶孢炭疽菌细胞骨架荧光标记菌株的构建

doi:10.13560/j.cnki.biotech.bull.1985.2020-1467

摘要/Abstract

摘要：

胶孢炭疽菌寄主广泛,能够引起众多植物产生炭疽病害。细胞骨架的结构及重排、极性分布都对菌丝生长、形态发生及致病性有着非常重要的作用,但是目前关于其菌丝生长及致病过程中细胞内骨架分布及动态变化情况还知之甚少。为了构建胶孢炭疽菌微丝及微管骨架的荧光标记菌株,采用随机重组及同源重组原理,成功构建了Lifeact-EGFP、MBD-EGFP及CgTUB1-EGFP标记重组菌株。激光共聚焦显微镜观察表明Lifeact-EGFP能够清晰地标记胶孢炭疽菌微丝骨架、CgTUB1-EGFP能够清晰地标记微管骨架;而MBD-EGFP标记的菌株细胞中荧光强度较低。进一步对标记菌株的生长发育及致病力等生理表型进行分析,结果表明Lifeact-EGFP及CgTUB1-EGFP的标记并不影响胶孢炭疽菌正常的生理功能,这两种标记菌株能够用于后续实验,为进一步研究其细胞骨架动态变化及骨架结合蛋白的功能打下基础。

关键词: 胶孢炭疽菌, 细胞骨架, 荧光标记

Abstract:

Colletotrichum gloeosporioides spp. is fungal pathogen that devastates crop plants worldwide. The structure,reorganization and polarization of cytoskeleton play essential roles in growth,morphogenesis and pathogenicity of filamentous fungi. However,the organization and dynamics of cytoskeleton during hyphae growth and infection of C. gloeosporioides is known little. To construct fluorescent labeled strains in the microfilament and microtubule skeleton of C. gloeosporioides,Lifeact-EGFP,MBD-EGFP and CgTUB1-EGFP labeled recombinant strains were successfully constructed by random recombination and homologous recombination. Laser confocal microscopy showed that Lifeact-EGFP clearly labeled the microfilament skeleton of C. gloeosporioides,and CgTUB1-EGFP clearly labeled the microtubule skeleton;whereas MBD-EGFP was not applicable for microtubule labeling. Further phenotypic analysis suggested that the fluorescence labeling of cytoskeleton by Lifeact-EGFP and CgTUB1-EGFP did not impact the normal physiological function. These 2 labeled strains can be used for further experiment,and lays a foundation for further investigating the dynamics of cytoskeleton and the functions of cytoskeleton-binding proteins.

Key words: Colletotrichum gloeosporioides, cytoskeleton, fluorescence labeling

刘娜, 刘世科, 王倩男. 胶孢炭疽菌细胞骨架荧光标记菌株的构建[J]. 生物技术通报, 2021, 37(8): 284-293.

LIU Na, LIU Shi-ke, WANG Qian-nan. Construction of a Strain with Fluorescence Labeling of Cytoskeleton in Colletotrichum gloeosporioides[J]. Biotechnology Bulletin, 2021, 37(8): 284-293.

图/表 7

图1 细胞骨架荧光标记载体原理图 A：利用Lifeact-EGFP标记微丝骨架原理图,LA：Lifeact编码序列,PgpdA：构巢曲霉3-磷酸甘油醛脱氢酶基因的启动子,TtrpC：构巢曲霉色氨酸合成基因trpC的终止子,HPT：潮霉素磷酸转移酶抗性基因;B：利用MBD-EGFP标记微丝骨架原理图,MBD：Microtubule binding domain;C：利用同源重组原理在CgTUB1基因下游敲入EGFP编码序列的原理图,WT：野生型菌株,Mutant：突变体,Flanking region：CgTUB1的下游序列

Fig. 1 Diagram of fluorescent labeled cytoskeleton vectors A: The diagram of microfilament labeling vector through Lifeact-EGFP; LA: coding sequence of Lifeact; PgpdA: promoter of glyceraldehyde-3-phosphate dehydrogenase in Aspergillus nidulans; TtrpC: terminator of tryptophan synthesis gene in Aspergillus nidulans; HPT：Hygromycin phosphate transferase resistance gene. B: The diagram of microtubule labeling vector through MBD-EGFP; MBD：microtubule binding domain. C: The diagram of inserting EGFP coding sequence behind gene CgTUB1 through homologous recombination; WT: wild type; Mutant: mutant strain; Flanking region: downstream of gene CgTUB1

表1 本实验所用引物

Table 1 Primers used in this study

引物名称Primer name	序列Primer sequences（5'-3'）	用途Purpose	内切酶位点Restriction enzyme
Lifeact-EGFP-F	tctagaATGGGTGTCGCAGATTTGA	Lifeact-EGFP扩增 Amplification for Lifeact-EGFP	Xba I
EGFP-R	gagctcTTACTTGTACAGCTCGTCC	Lifeact-EGFP扩增 Amplification for Lifeact-EGFP	Sac I
MBD-EGFP-F	tctagaATGAGCCTCGCCTCAGG	MBD-EGFP扩增 Amplification for MBD-EGFP	Xba I
EGFP-R	gagctcTTACTTGTACAGCTCGTCC	MBD-EGFP扩增 Amplification for MBD-EGFP	Sac I
CgTub-SF	tctagaAGCCCTACAACGCCACT	CgTUB1 DNA 3'端扩增 Amplification for CgTUB1 DNA 3'	Xba I
CgTub-R	ggtaccAACCTCCTCCTCAAGAGG	CgTUB1 DNA 3'端扩增 Amplification for CgTUB1 DNA 3'	Kpn I
hph-SPLR	GGATGCCTCCGCTCGAAGTA	HPT-5'端扩增 Amplification for HPT-5'	-
hph-SPLF	CGTTGCAAGACCTGCCTGAA	HPT-3'端扩增 Amplification for HPT-3'	-
CgTub-MR2	GCAGTTATTAGACTGCGCAACTGG- TTCCCGGTCGG	HPT-3'端扩增 Amplification for HPT-3'	-
CgTub-MF2	CCGACCGGGAACCAGTTGCGCAGT- CTAATAACTGC	CgTUB1下游序列扩增 Amplification for CgTUB1 downstream fragment	-
CgTub-3R	TGCCTATACCGAACACGATC	CgTUB1下游序列扩增 Amplification for CgTUB1 downstream fragment	-
CgTubegfp-JCF	ACTGACCTTCGCTCCTACCCA	敲入重组菌株检测 PCR diagnosis of the CgTUB1-EGFP labeling strains	-
CgTubegfp-JCR	TGCCGTTCTTCTGCTTGTCG	敲入重组菌株检测 PCR diagnosis of the CgTUB1-EGFP labeling strains	-
HPT-JCF	ACAGCGGTCATTGACTGGAGCGA	敲入重组菌株检测 PCR diagnosis of the CgTUB1-EGFP labeling strains	-
CgTub-JC3R	GCCCTTTGGAATACCCATCTC	敲入重组菌株检测 PCR diagnosis of the CgTUB1-EGFP labeling strains	-

图2 细胞骨架荧光标记重组菌株的PCR鉴定 A：Lifeact-EGFP标记微丝骨架重组菌株的PCR检测结果;B：MBD-EGFP标记微管骨架重组菌株的PCR检测结果;C：EGFP敲入CgTUB1基因位点重组菌株上游重组片段PCR检测结果;D：EGFP敲入CgTUB1基因位点重组菌株下游重组片段PCR检测结果;M：DNA marker DM5000

Fig. 2 PCR diagnosis of cytoskeleton labeling recombinant strains A: PCR diagnosis of microfilament labeling strains by Lifeact-EGFP. B：PCR diagnosis of microtubule labeling strains by MBD-EGFP. C: PCR diagnosis of the upstream recombinant fragment of CgTUB1-EGFP labeling strains. D: PCR diagnosis of the downstream recombinant fragment of CgTUB1-EGFP labeling strains. M: DNA marker DM5000

图3 荧光标记重组菌株孢子中的细胞骨架结构 CK：表达EGFP的对照菌株;Lifeact-EGFP：微丝骨架标记重组菌株;CgTUB1-EGFP：微管骨架标记重组菌株;Z Projection：Z轴切片图像的叠加图;Scale bar：5 μm。下同

Fig. 3 Cytoskeleton structure in conidiophores of fluorescent labeled recombinant strains CK: Control strain expressing EGFP; Lifeact-EGFP: microfilament labeled recombinant strain; CgTUB1-EGFP: microtubule labeled recombinant strain; Z Projection：stacked image of Z-series slices; scale bar：5 μm. The same below

图4 荧光标记重组菌株菌丝中的细胞骨架结构

Fig. 4 Cytoskeleton structure in the hypha of fluorescent labeled recombinant strains

图5 野生型菌株与重组菌株菌落直径及产孢量 A：在PDA培养基上培养时不同菌株的菌落直径;B：在PDB液体培养基中培养时不同菌株的孢子产量;WT：野生型菌株

Fig. 5 Clony diameters and conidiations of WT and mutant strains A: Clony diameter of WT and mutant strains on PDA media; B: conidiation of WT and mutant strains on PDB liquid media; WT: wild type strain

图6 接种野生型菌株与重组菌株后橡胶树叶片的发病情况及病斑直径 A：接种病原菌3 d后橡胶树叶片的发病情况;B：接种病原菌2、3 d后橡胶树叶片的病斑直径

Fig. 6 Virulence assay on rubber tree leaves and lesion diameter after inoculation with WT and recom-binant strains A: Disease symptoms of rubber tree leaves at day 3 after inoculation (dpi); B: Mean lesion diameters of rubber tree leaves at day 2 and 3 (dpi).

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